|Publication number||US7019541 B2|
|Application number||US 10/846,910|
|Publication date||Mar 28, 2006|
|Filing date||May 14, 2004|
|Priority date||May 14, 2004|
|Also published as||US20050253601, WO2005114231A1|
|Publication number||10846910, 846910, US 7019541 B2, US 7019541B2, US-B2-7019541, US7019541 B2, US7019541B2|
|Inventors||Michael E. Kittrell|
|Original Assignee||Crown Products, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (18), Referenced by (57), Classifications (16), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
The invention described hereinbelow relates to volatile fluids transport and storage systems. More particularly, said invention relates to such systems which incorporate structure adapted for separation of water from the volatile fluids, and which are adapted for collection of such water at a water collection point, said invention further relating to apparatus applicable to such water collection point and which are adapted for probing or testing for excessive water accumulations.
An environment in which the instant inventive electric conductivity water probe may be advantageously used is an airport aircraft maintenance tarmac. In such environment, a fuel truck having a tank for transporting aircraft fuel commonly services aircrafts by pumping fuel into an aircraft's fuel tanks. Water, which upon occasion undesirably collects within and contaminates the tank of such a fuel truck, is necessarily prevented from being pumped into the aircraft's fuel tanks.
A common means for preventing water contaminated fuel from being pumped into an aircraft's fuel tanks is to interpose a water separating vessel or tank in line with a fuel transmission line extending between such truck and such aircraft. Such vessel commonly encases a first stage water coalescing element and a second stage water separating element, and has a fuel inlet port, a fuel outlet port, a low end water collecting sump, and a purging port for draining water from the sump.
In normal operation of such water separating vessels, only small amounts of water are expected to be separated from fuel which is pumped therethrough during a single aircraft refueling process. Such small volume of water is conveniently purged immediately following each aircraft fueling operation. However, on occasion, an excessive amount of water may be present within a fuel truck's tank, resulting in transmission of an excessive amounts of water to the water separating vessel. In the event water within the sump of such water separating vessel rises to a level at which portions of the vessel's coalescing and separating elements are submerged in water, the vessel's ability to further separate water from fuel may become compromised. Such a malfunction of the water separator potentially allows water laden fuel to be pumped into an aircraft's fuel tanks. In-flight aircraft engine failure and a catastrophic crash can result when the engine ingests water contaminated fuel.
In order to provide a safeguard against pumping water laden aircraft fuel downstream from a water separating vessel, means for detecting dangerously high water accumulations within such water separating vessels are commonly provided, such means operatively triggering, for example, a fuel truck pump motor “kill” switch. Electric conductivity water probes are a preferred means for detecting high water levels within such water separating vessels. Such probes desirably eliminate mechanical moving parts and avoid requirements of maintaining narrow buoyancy parameters which are inherent in fuel/water mechanical float switches.
Where an electric conductivity probe is utilized as a high water level testing means within such water separating vessel, the electrode or electric circuit completion point of such probe is typically mounted within or upon a wall of such water separating vessel in an orientation wherein the electrode is normally bathed and non-electrically conductive aircraft fuel. Under normal operating conditions, in the event that electrically conductive water rises within such water separating vessel to the level of such electrode, the aircraft fuel is washed away from the electrode by the water, and the water immediately completes an electric circuit which is communicated electrically for operation of, for example, a pump motor kill switch. However, aircraft fuel pumped through the water separator vessel may, on occasion, be further contaminated (over and above water contamination) by electrically insulating substances which tend to coat the electrode, acting as an electrical insulator. Where such electrode coating contaminants are present, excess water within the water separating vessel will not necessarily complete an electric circuit within the water probe. In such event, the aforementioned exemplary pump motor kill switch may not be actuated in response to an excess water event, and water laden fuel may be undesirably pumped downstream and into an aircraft's fuel tank.
A method for protecting against foreign matter deposit induced electric conductivity water probe failure is to shut down and disassemble the water separating vessel, exposing the interior electrical contact point or electrode to visual inspection. However, such measures are mechanically complex and time consuming, resulting in an undesirable aircraft refueling system down time.
Another known method of protecting against such foreign matter deposit induced electric conductivity water probe failure is to purposefully create high water conditions within the water separating vessel, and to observe the function of the water probe during the known high water event. However, such protective procedures similarly are time consuming, and undesirably result in aircraft fueling system down time.
The instant inventive electric conductivity water probe solves or ameliorates all of the problems set forth above by providing an electric conductivity water probe which is capable of normally functioning as a water test probe and which is further capable of alternately performing a function of “mimicking” a high water event within a water separating vessel without requiring the occurrence of an actual high water event.
A major structural component of the instant invention comprises a walled electric conductivity water presence testing chamber having an interior space or bore. Said chamber necessarily has a fluids input/output port for facilitating an inward flow from a water separating vessel of, for example, normally present non-conductive jet fuel, and for alternately facilitating, in the event of high water within such vessel, simultaneous outwardly and inwardly crossing flows of the fuel and water.
First valve means are necessarily connected operatively to the fluids input/output port, said means being adapted for alternately permitting and resisting flows of fluids through the fluids input/output port. The first valve means may suitably comprise any of numerous commonly known “on/off” or “shutoff” flow controlling valves such as gate valves, ball valves, rotary spool valves, globe valves, angle valves, and the like. Preferably, the first valve means comprises a rotary spool or ball valve whose spool or ball includes a three port “T” channel, such valve performing functions (described below) over and above simply opening and closing the fluids input/output port. Preferably, an outer end of the test chamber's fluids input/output port comprises tank port mounting means allowing the fluids input/output port to be fixedly attached to, for example, the wall of a water collecting sump mounted at a low end of a jet fuel water separating vessel. Assuming that such sump has a helically threaded high water testing port, the tank port mounting means preferably comprises matching helical threads.
In addition to the above described fluids input/output port, the test chamber necessarily has a water input port situated inwardly from the first valve means. Said first valve means may be actuated to resist fluid flow through the fluids input/output port. Thereafter, electrically non-conductive jet fuel trapped within the test chamber may be purged, suitably by withdrawing the jet fuel through the water input port. More desirably, such fuel is purged through a separate fluids output port. Thereafter, the test chamber may be completely filled with a volume of electrically conductive water.
In order for electric conductivity water presence testing to be performed upon such volume of water, the wall of the test chamber preferably comprises a first wall section and at least a second wall section, the at least second section being electrically isolated or insulated from the first section. An electrical potential difference or voltage between the first and the at least second wall sections may be induced by allowing the first wall section to serve as an electrical ground, and by extending an electrically conductive lead wire outwardly from the at least second wall section to a voltage source. The volume of electrically conductive water which simultaneously bathes the first and at least second wall sections electrically bridges across the insulator and completes an electric circuit, facilitating passage of an electric current which may be communicated electrically for activation of, for example, a pump motor kill switch.
Like the fluids input/output port, the water input port is similarly preferably controlled by valve means, which may suitably comprise a separate gate valve, ball valve, rotary spool valve, globe valve, angle valve, removable plug, or removable cap. Notwithstanding, the water input port controlling valve means preferably comprises the same “T” ported rotary spool or ball valve which controls fluids flow through the fluids input/output port. Preferably, such shared valve member closes the water input port upon opening of the fluids input/output port, and alternately opens the water input port upon closure of the fluids input/output port.
Preferably, the electrically isolated at least second wall section comprises an electrode having a wire lead extending outwardly from an outer end, the electrode extending through a plastic sleeve insulator.
In operation of the instant inventive electric conductivity water probe, the fluids input/output port is normally open, the water input port is normally closed, and the fluids output port, if any, is normally closed. Assuming that an outer end of the fluids input/output port is connected to a high water level testing port of a water collection sump of a vessel adapted for separating water from fuel, such fuel normally flows through the fluids input/output port and normally fills the test chamber. Since aircraft fuel is normally electrically non-conductive, the fuel prevents the completion of an electric circuit between the electrically isolated first and at least second wall sections (e.g. between the typically metal wall casing of the test chamber and the insulated electrode extending through such wall). In the event that collected water rises within the water separating vessel to the level of the fluids input/output port, the water flows into the fluids input/output port while displacing and causing aircraft fuel within the test chamber to flow outwardly from the fluids input/output port, filling the test chamber with water. Since the water is normally electrically conductive, the water completes an electric circuit between the first and at least second wall sections of the test chamber.
A factor complicating the process described above results from further contamination of the fuel. Jet fuel potentially includes contaminants which are capable of coating the interior surfaces of the first and at least second wall sections of the test chamber, further electrically isolating those sections from each other. Where such surface coating contamination occurs, a high water event as described above may fill the test chamber with water without completing an electric circuit between the at least first and second wall sections. In such event, the electric conductivity water probe may undesirably fail to detect a high water event.
Periodic actuation of the instant invention's ability to “mimic” a high water event provides protections against undesirable high water detection failures as described above without requiring flooding of the water separating vessel with water. In order to cause the instant inventive electric conductivity water probe to mimic a high water event, the first valve means is actuated to close the fluids input/output port. Thereafter, fuel contained within the test chamber is purged, preferably by opening and reclosing a valve controlled fluids output port. Thereafter, the water input port is opened, and water is poured therethrough, filling the test chamber with electrically conductive water. In the event such water completes an electric circuit between the first and at least second wall sections of the test chamber, an operator may accurately infer that electric contact surfaces within such chamber have not been undesirably coated by any contaminants, and the operator may infer that the probe is properly functioning. Thereafter, the water may be purged through the fluids output port, and both the water input port and the fluids output port are thereafter closed. Thereafter, the fluids input/output port is reopened, restoring the test probe to normal water level testing function.
Accordingly, an object of the instant invention is to provide an electric conductivity water probe which incorporates structural features, adapting the probe for periodically “mimicking” a high water event, such probe providing assurances, over time, of the probe's electrical testing integrity.
Other and further objects, benefits, and advantages of the instant invention have been described above, and further appear in the Detailed Description and drawings which follow.
Referring now to the drawings, and in particular to
Referring simultaneously to
Referring further simultaneously to
Referring further simultaneously to
Referring further simultaneously to
Referring simultaneously to
In operation of the instant inventive electric conductivity water probe 10, referring simultaneously to
During normal operations referring further to
Referring further simultaneously to
Referring further simultaneously to
In order to guard against and prevent the occurrence of a water presence testing failure such as described above, the electric conductivity water probe 10 may be periodically operated to “mimic” a high water event. Mimicking a high water event desirably reproduces high water conditions within a water separator (see
Referring simultaneously to all figures, reversal of steps described above purges water from “T” channel 30 and restores the electric conductivity water probe 10 to its normal operating configuration as depicted in
While the principles of the invention have been made clear in the above illustrative embodiment, those skilled in the art may make modifications in the structure, arrangement, portions and components of the invention without departing from those principles. Accordingly, it is intended that the description and drawings be interpreted as illustrative and not in the limiting sense, and that the invention be given a scope commensurate with the appended claims.
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|U.S. Classification||324/696, 73/863.73, 73/863.72, 137/625.47, 137/172, 324/694, 73/863.71|
|International Classification||G01R27/08, G01N33/18, G01N27/06|
|Cooperative Classification||Y10T137/3006, Y10T137/86871, G01N27/06, G01N33/1886|
|European Classification||G01N33/18P, G01N27/06|
|May 14, 2004||AS||Assignment|
Owner name: CROWN PRODUCTS, INC., KANSAS
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:KITTRELL, MICHAEL E.;REEL/FRAME:016031/0631
Effective date: 20040429
|Apr 22, 2009||FPAY||Fee payment|
Year of fee payment: 4
|Sep 6, 2013||FPAY||Fee payment|
Year of fee payment: 8